Improvement of the Tm3+:3H4 level lifetime in silica optical fibres by lowering the local phonon energy

TL;DR

This study demonstrates that modifying silica glass with specific network modifiers can significantly enhance the lifetime and quantum efficiency of Tm3+ ions, improving near-infrared fluorescence for optical fiber applications.

Contribution

It provides new insights into how glass network modifiers influence Tm3+ spectroscopic properties and introduces a microscopic model to predict quantum efficiency limits.

Findings

Adding AlO3/2 increases Tm3+ lifetime to 50 μs.

Quantum efficiency improves from 2% to 8% with AlO3/2.

PO5/2 decreases lifetime to 9 μs.

Abstract

The role of some glass network modifiers on the quantum efficiency of the near-infrared fluorescence from the 3H4 level of Tm3+ ion in silica-based doped fibres is studied. Modifications of the core composition affect the spectroscopic properties of Tm3+ ion. Adding 17.4 mol% of AlO3/2 to the core glass caused an increase of the 3H4 level lifetime up to 50 $\mu$s, 3.6 times higher than in pure silica glass. The quantum efficiency was increased from 2% to approximately 8%. On the opposite, 8 mol% of PO5/2 in the core glass made the lifetime decrease downto 9 $\mu$s. These changes of Tm3+ optical properties are assigned to the change of the local phonon energy to which they are submitted by modifiers located in the vicinity of the doping sites. Some qualitative predictions of the maximum achievable quantum efficiency are possible using a simple microscopic model to calculate the non-radiative de-excitation rates.